Pressure proportional control valve

ABSTRACT

A pressure proportional control valve for controlling the pressure of an operation fluid, such as the air, in proportion to the output of an electromagnetic operation member.

FIELD OF THE INVENTION

The present invention relates to a pressure proportional control valve for controlling a pressure of an operation fluid such as the air or the like. More specifically, the invention relates to a pressure proportional control valve for controlling the pressure in proportion to the output of the electromagnetic operation means.

DESCRIPTION OF THE RELATED ART

In a pressure proportional control valve for controlling the pressure in proportion to the output of the electromagnetic operation means, there is generally used a spool valve in which a spool arranged to be allowed to slide in a sleeve is operated to a position where the attractive force of an electromagnetic solenoid is balanced with the reactive force of a spring.

The spool valve is so constituted that the spool slides along the inner peripheral surface of the sleeve having ports formed in its side face, making it necessary to form a clearance between the sleeve and the spool but inhibiting the use of a seal such as a rubber or the like. Therefore, it is not possible to attain a complete sealing. To enhance the sealing between the sleeve and the spool, the clearance between them must be as small as possible, but yet retaining sliding performance. In order to fulfill this requirement, however, the machining of a high degree of precision is required, which results in an increase in cost of machining. Further, the spool valve causes malfunction if dust and the like enters between the sleeve and the spool.

In order to solve the above problems of the spool valve-type pressure proportional control valve, there has been also proposed a poppet valve-type pressure proportional control valve. This type of pressure proportional control valve comprises a poppet valve, a diaphragm and an electromagnetic operation means as disclosed in Japanese Unexamined Utility Model Publication (Kokai) No. 14757/1993.

Due to its structure, the pressure proportional control valve disclosed in the above Japanese Unexamined Utility Model Publication (Kokai) No. 14757/1993 is of the type of two-way valve in which another valve for changing over from feeding to exhausting must be used in combination. Therefore, problems arise that the fluid circuit constitution becomes complex and in addition, another valve used in combination operates very frequently.

SUMMARY OF THE INVENTION

The present invention has been done in view of the above-mentioned facts, and its principal object is to provide a pressure proportional control valve of a type of three-way valve capable of controlling the pressure in proportion to the output of the electromagnetic operation means by using a poppet valve means, which has good sealing.

In order to accomplish the above object according to the present invention, there is provided a pressure proportional control valve comprising a valve body having an input port, an output port and an exhaust port; a valve means arranged in the valve body to control a communication with the ports; and an electromagnetic operation means for driving the valve means; which is characterized in:

that the valve body is provided with a communication chamber for communicating the input port with the output port and two valve holes formed, being faced to each other, on both sides of the communication chamber, the communication chamber having an annular partitioning plate arranged therein;

that the valve means comprises a first valve body having a slide portion provided at one end portion thereof so as to be slidably fitted to one of valve holes, a first valve portion having a tapered surface, which is formed at a central portion thereof and comes in contact with a seat portion formed on the inner periphery of the annular partitioning plate, a second valve portion provided at the other end portion thereof, and a communication path that penetrates through in the axial direction and communicates with the exhaust port; a second valve body having a slide portion slidably fitted to the other valve hole, a valve portion that is provided at one end portion thereof and comes in contact with the second valve portion of the first valve body, and a communication path that penetrates through in the axial direction and communicates with the exhaust port; a first seal arranged between the slide portion of the first valve body and the inner peripheral surface of the one valve hole; a second seal arranged between the slide portion of the second valve body and the inner peripheral surface of the other valve hole; a first spring for urging the first valve body in a direction in which the first valve portion comes in contact with the seat portion of the partitioning plate; and a second spring that is disposed between the first valve body and the second valve body and urges the first valve body and the second valve body in a direction in which they are separated away from each other; wherein a diameter of the slide surface of the first seal, a diameter of a contact portion at which the first valve portion of the first valve body comes in contact with the seat portion of the partitioning plate and a diameter of a contact portion at which the valve portion of the second valve body comes in contact with the second valve portion of the first valve body are set to be equal; and the diameter of the slide surface of the second seal is set to be larger than the diameter of the slide surface of the first seal; and

that when energized, the electromagnetic operation means operates to move the second valve body toward the first valve body side.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view illustrating a first embodiment of a pressure proportional control valve constituted according to the present invention;

FIG. 2 is a diagram illustrating the spring characteristics of the first and second springs constituting the pressure proportional control valve shown in FIG. 1;

FIG. 3 is a sectional view illustrating a first operation state of the pressure proportional control valve shown in FIG. 1; and

FIG. 4 is a sectional view illustrating a second operation state of the pressure proportional control valve shown in FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

A preferred embodiment of the pressure proportional control valve constituted according to the present invention will now be described with reference to the accompanying drawings.

FIG. 1 is a sectional view of a pressure proportional control valve constituted according to the present invention.

A pressure proportional control valve 2 according to the illustrated embodiment comprises a valve body 3, a valve means 4 arranged in the valve body 3, and an electromagnetic operation means 5 for driving the valve means 4. In the illustrated embodiment, the valve body 3 is constituted by two body pieces 3 a and 3 b. The valve body 3 thus constituted by two body pieces 3 a and 3 b has an input port 31, an output port 32 and an exhaust port 33. In the central portion of the valve body 3, there is formed a communication chamber 34 for communicating the input port 31 with the output port 32. The valve body 3 is further provided with two valve holes 35 a and 35 b formed on both sides of the communication chamber 34 in such a manner of facing each other. One valve hole 35 a is formed in the central portion of one body piece 3 a, is opened in the communication chamber 34 and communicates with the exhaust port 33. The other valve hole 35 b is formed in the central portion of the other body piece 3 b on the same axis as the valve hole 35 a, and is opened in the communication chamber 34. The diameter of the other valve hole 35 b is greater than the diameter of the one valve hole 35 a. Further, a stopper 351 b is formed at the right end in the drawing of the other valve hole 35 b so as to protrude inward in the radial direction. An annular partitioning plate 36 is arranged in the communication chamber 34 formed in the valve body 3 constituted by two body pieces 3 a and 3 b, and the communication chamber 34 is divided into an input-side chamber 34 a and an output-side chamber 34 b by the partitioning plate 36 and by a valve means 4 that will be described later.

The valve means 4 arranged in the valve body 3 has a first valve body 41 arranged in the one valve hole 35 a so as to slide and a second valve body 42 arranged in the other valve hole 35 b so as to slide. The first valve body 41 has a slide portion 411 that is provided at one end portion thereof and is slidably fitted in the valve hole 35 a, a central small-diameter portion 412, a first valve portion 413 having a tapered surface, which is formed between the slide portion 411 and the central small-diameter portion 412 and comes in contact with a seat portion 361 formed on the inner periphery of the partitioning plate 36, and a second valve portion 414 provided at the other end portion. The slide portion 411 constituting the first valve body 41 has an outer diameter (D1) equal to the outer diameter (D2) of the second valve portion 414. The first valve body 41 has a communication path 415 penetrating through in the axial direction, and the communication path 415 communicates with the exhaust port 33 through a first pressure chamber 37 formed between one end, i.e., left end in FIG. 1, of the first valve body 41 and the body piece 3 a. A first seal 43 that is in sliding contact with the outer peripheral surface of the slide portion 411 is mounted on a part of the inner peripheral surface of the valve hole 35 a formed in the body piece 3 a. The first seal 43 separates the input-side chamber 34 a or the input port 31 of the communication chamber 34 from the first pressure chamber 37 or the exhaust port 33.

The second valve body 42 slidably arranged in the valve hole 35 b has a slide portion 421 fitted into the valve hole 35 b so as to slide and a valve portion 422 provided at one end portion thereof, i.e., on the side of an end portion facing the first valve body 41. The outer diameter (D3) of the slide portion 421 is greater than the outer diameter (D1) of the slide portion 411 of the first valve body 41. The valve portion 422 constituting the second valve body 42 has a seat portion 422 a having a tapered inner peripheral surface, which is formed at an end facing the second valve portion 414 of the first valve body 41 and will come in contact with the outer peripheral edge of the second valve portion 414. The second valve body 42 has a communication path 423 penetrating through in the axial direction. The communication path 423 communicates with the exhaust port 33 through the communication path 415 formed in the first valve body 41 and the first pressure chamber 37, and further communicates with the second pressure chamber 38 formed at the other end side, i.e., on the right in FIG. 1, of the second valve body 42. Therefore, the first pressure chamber 37 communicates with the second pressure chamber 38 through the communication path 415 formed in the first valve body 41 and through the communication path 423 formed in the second valve body 42. A second seal 44 that is in sliding contact with the outer peripheral surface of the slide portion 411 is mounted on a portion of the inner peripheral surface of the valve hole 35 b formed in the body piece 3 b. The second seal 44 separates the output-side chamber 34 b or the output port 32 of the communication chamber 34 from the second pressure chamber 38 or the exhaust port 33.

In the illustrated embodiment, a diameter of the slide surface that comes in sliding contact with the first seal 43 or an outer diameter (D1) of the slide portion 411 of the first valve body 41, a diameter (D4) of the contact portion at which the first valve portion 413 having a tapered surface of the first valve body 41 comes in contact with a seat portion 361 of the partitioning plate 36 (i.e., a diameter of the seat portion 361 of the partitioning plate 36), and a diameter (D5) of the contact portion of a seat portion 422 a, which is the inner peripheral surface of the second valve body 42 and will come in contact with the outer peripheral edge of the second valve portion 414 of the first valve body 41 (an outer diameter (D2) of the second valve portion 414), are constituted to be equal to each other. The diameter of the slide surface that comes in sliding contact with the second seal 44 or the outer diameter (D3) of the slide portion 421 of the second valve body 42 is greater than the above-mentioned diameters. In the illustrated embodiment, since the first seal 43 and the second seal 44 are mounted on the valve body 3, the diameter of the slide surface in sliding contact with the seal becomes the outer diameter (D1) of the slide portion 411 of the first valve body 41 and the outer diameter (D3) of the slide portion 421 of the second valve body 42. When the first seal 43 and the second seal 44 are mounted on the first valve body 41 and on the second valve body 42, however, the diameter of the slide surface that comes in sliding contact with the seals becomes the inner diameter of the valve hole 35 a and of the valve hole 35 b formed in the valve body 3.

A first compression coil spring 45 is disposed in the first pressure chamber 37, and urges the first valve body 41 toward the right in FIG. 1, i.e., in a direction in which the first valve portion 413 of the first valve body 41 comes in contact with the seat portion 361 of the partitioning plate 36. Further, a second compression coil spring 46 is arranged between the first valve body 41 and the second valve boy 42, and urges the both valve bodies in a direction in which they separate away from each other. Here, the spring characteristics and setting pressures of the first compression coil spring 45 and of the second compression coil spring 46 will be described with reference to FIG. 2.

The first compression coil spring 45 has a length L1 in its free state and, when set, is compressed up to a first set position S1. The set load at this moment is denoted by SF1. A load of the thus set first compression coil spring 45 varies linearly from the first set position S1 up to a compression end position S0 along a first coil spring-load line SL1. The second compression coil spring 46 has a length L2 in its free state and, when set, is compressed up to a second set position S2. The set load at this moment is denoted by SF2. A load of the thus set second compression coil spring 46 varies linearly from the second set position S2 up to the first set position S1, where the second valve body 42 comes in contact with the first valve body 41, along a second coil spring-load line SL2. The spring-load in a state where the second compression coil spring 46 is compressed up to the first set position S1, that is, the load of the second compression coil spring 46 at its full stroke is SF21, which is smaller than the set load SF1 of the first compression coil spring 45. The first coil spring-load line SL1 of the first compression coil spring 45 and the second coil spring-load line SL2 of the second compression coil spring 46 have the same angle of inclination, i.e., have the same spring constant. It is desired that the loads of the first compression coil spring 45 and of the second compression coil spring 46 are set to be very small values of levels that do not almost affect the balance of pressures.

When the first compression coil spring 45 and the second compression coil spring 46, both having the above-mentioned spring constants, are arranged as shown in FIG. 1, the first valve portion 413 of the first valve body 41 comes in contact with the seat portion 361 of the partitioning plate 36 due to the spring-load of the first compression coil spring 45, and the right end in the drawing of the second valve body 42 is brought into contact with the stopper 351 b. In a set state as shown in FIG. 1, therefore, a gap is formed between the seat portion 422 a which is the inner peripheral tapered surface constituting the valve seat portion 422 of the second valve body 42 and the outer peripheral edge of the second valve portion 414 that constitutes the first valve body 41.

Next, described below is the electromagnetic operation means 5 for driving the above-mentioned valve means 4.

The electromagnetic operation means 5 according to the illustrated embodiment comprises a casing 51 mounted to the right end in the drawing of the body piece 3 b that constitutes the valve body 3, an electromagnetic coil unit 52 disposed in the casing 51, a fixed yoke 53 forming a magnetic path generated by the electromagnetic coil unit 52, a moving yoke 54 attracted by the magnetic force generated by the fixed yoke 53 in the electromagnetic coil unit 52, and an operation rod 55 linked to the moving yoke 54. The casing 51 comprises a cylindrical main body 51 a made of a magnetic material and a guide member 51 b that is mounted on the right end in the drawing of the cylindrical main body 51 a and is made of a magnetic material. The guide member 51 b is constituted by a cylindrical portion 511 b and an annular portion 512 b formed, at an intermediate portion of the cylindrical portion 51 b in the axial direction, protruding outward in the radial direction. The thus formed guide member 51 b is fitted, at a portion on the left side in the drawing of the annular portion 512 b of the cylindrical portion 511 b, into a center hole 521 a of a bobbin 521 that will be described later, of the electromagnetic coil unit 52, and the annular portion 512 b is secured to the right end in the drawing of the main body 51 a. The electromagnetic coil unit 52 is constituted by an annular bobbin 521 made of a suitable synthetic resin and a coil 522 wound on the bobbin 521.

The fixed yoke 53 is made of a magnetic material, and is constituted by a cylindrical portion 531 and an annular portion 532 formed, at an intermediate portion of the cylindrical portion 531 in the axial direction, protruding outward in the radial direction, the annular portion 532 being held between the body piece 3 b and the electromagnetic coil unit 52. Further, the cylindrical portion 531 constituting the fixed yoke 53 is fitted, at a portion on the left in the drawing of the annular portion 532, into a fitting hole 302 b formed in the body piece 3 b, and is fitted, at a portion on the right in the drawing of the annular portion 532, into the center hole 521 a of the annular bobbin 521 constituting the electromagnetic coil unit 52. The cylindrical portion 531 constituting the fixed yoke 53 has an insertion hole 531 a formed in the central portion thereof penetrating through in the axial direction, as well as a plurality of communication holes 531 b penetrating through in the axial direction on the outer side of the insertion hole 531 a in the radial direction. A seal 533 is mounted on the outer periphery of a portion on the left in the drawing of the annular portion 532 of the cylindrical portion 531 constituting the fixed yoke 53 thereby to seal a gap relative to the inner peripheral surface of the fitting hole 302 b of the body piece 3 b.

The moving yoke 54 is made of a magnetic material, is arranged in the cylindrical portion 511 b of the guide member 51 b constituting the casing 51, and is so constituted as to be allowed to approach and separate away, on the right side in FIG. 1 of the fixed yoke 53. The moving yoke 54 has a fitting hole 54 a formed, in the central portion thereof, penetrating through in the axial direction, and has a communication hole 54 b penetrating through in the axial direction on the outer side of the fitting hole 54 a in the radial direction. The operation rod 55 is made of a nonmagnetic material such as a stainless steel or the like, disposed being inserted in the insertion hole 31 a formed in the center of the cylindrical portion 531 that constitutes the fixed yoke 53, and is supported by a bush 535 fitted to the inner peripheral surface of the insertion hole 531 a so as to slide in the axial direction. In FIG. 1, the operation rod 55 is fitted, at its right end, to the fitting hole 54 a of the moving yoke 54, and is so constituted as to operate integrally with the moving yoke 54 in the axial direction. The left end, i.e., the front end in FIG. 1 of the operation rod 55 is so constituted as to come in contact with the right end in FIG. 1 of the second valve body 42.

A support member 56 for supporting the right end, i.e., the rear end, in FIG. 1 of the operation rod 55 is arranged at the right end of the cylindrical portion 511 b of the guide member 51 b that constitutes the casing 51. This support member 56 has a fitting portion 561 and a flange portion 562 formed at the right end in FIG. 1 of the fitting portion 561, and the fitting portion 561 is fitted to the cylindrical portion 511 b. The fitting portion 561 has an insertion hole 561 a formed in the center thereof penetrating through in the axial direction, and has a plurality of communication holes 561 b formed on the outer side of the insertion hole 561 a in the radial direction penetrating through in the axial direction. A bush 563 is fitted into the insertion hole 561 a formed in the fitting portion 561, and the right end in FIG. 1 of the operation rod 55 is supported by the bush 563 so as to slide. A cover member 57 is mounted on the outer periphery at the right end of the cylindrical portion 511 b of the guide member 51 b that constitutes the casing 51. The cover member 57 is constituted by a cylindrical portion 571 and a bottom portion 572 provided at the right end in FIG. 1 of the cylindrical member 571, and the cylindrical portion 571 is mounted by being screwed onto a threaded portion formed on the outer periphery at the right end of the cylindrical portion 511 b of the guide member 51 b. A seal 58 is mounted on the outer periphery at the right end of the cylindrical portion 511 b of the guide member 51 b to seal a gap relative to the inner peripheral surface of the cylindrical portion 571 that constitutes the cover member 57. A packing 59 is disposed between the inner surface of the bottom portion 572 that constitutes the cover member 57 and the flange portion 562 of the support member 56, and a third pressure chamber 60 is formed between the bottom portion 572 that constitutes the cover member 57 and the flange portion 562 of the support member 56. The third pressure chamber 60 communicates with the second pressure chamber 38 through the communication hole 561 b formed in the support member 56, communication hole 54 b formed in the moving yoke 54 and the communication hole 531 b formed in the fixed yoke 53. The second pressure chamber 38 and the first pressure chamber 37 communicate together through a communication path 423 formed in the second valve body 42 and a communication path 415 formed in the first valve body 41. Therefore, the first pressure chamber 37, the second pressure chamber 38 and the third pressure chamber 60 are made to communicate with one another.

The pressure proportional control valve 2 according to the illustrated embodiment is constituted as described above. The operation will now be described with reference to FIGS. 3 and 4.

FIG. 1 shows a state where no voltage is applied to the coil 522 of the electromagnetic coil unit 52 that constitutes the electromagnetic operation means 5. In this state as described above, the first valve unit 413 of the first valve body 41 comes in contact with the seat portion 361 of the partitioning plate 36, and a gap is formed between the seat portion 422 a of the second valve body 42 and the outer peripheral edge of the second valve portion 414 that constitutes the first valve body 41. Therefore, the communication between the input port 31 and the output port 32 is interrupted, and the output port 32 is connected with the exhaust port 33 through the output-side chamber 34 b in the communication chamber 34, the gap between the seat portion 422 a of the second valve body 42 and the second valve portion 414 that constitutes the first valve body 41, the communication passage 415 formed in the first valve body 41 and the first pressure chamber 37. As a result, the operation chamber of the actuator (not shown) connected to the output port 32 through a pipe (not shown) communicates with the exhaust port 33 and hence, the actuator is maintained in the non-operating condition.

Here, description will be made of the pressure balance of the first valve body 41 in a state shown in FIG. 1.

A pressure in the input port 31 acts on the first valve body 41. Here, however, since the outer diameter (D1) of the slide portion 411 of the first valve body 41, which is the diameter of the slide surface that is in sliding contact with the first seal 43, is equal to the diameter (D4) of the portion at which the first valve portion 413 of the first valve body 41 comes in contact with the partitioning plate 36, a thrust to the first valve body 41 is not produced by the pressure in the input port 31.

Further, the pressures in the output port 32 and in the exhaust port 33 act on the first valve body 41. Here, however, since the outer diameter (D1) of the slide portion 411, the outer diameter (D2) of the second valve portion 414 and the diameter (D4) of the portion at which the first valve portion 413 of the first valve body 41 comes in contact with the partitioning plate 36 are equal to each other, a thrust to the first valve body 41 is not produced by the pressure in the output port 32.

When a predetermined voltage is applied to the coil 522 of the electromagnetic coil unit 52 that constitutes the electromagnetic operation means 5 in the state shown in FIG. 1, a magnetic path is formed through the fixed yoke 53, and the moving yoke 54 that has been attracted by the fixed yoke 53 moves toward the left in FIG. 1. With the motion of the moving yoke 54, the operation rod 55 moves toward the left to cause the second valve body 42 to move toward the left against the spring force of the second compression coil spring 46. As a result, the seat surface 422 a of the second valve body 42 comes in contact with the outer peripheral edge of the second valve portion 414 that constitutes the first valve body 41 and, further, causes the first valve body 41 to move toward the left against the spring force of the first compression coil spring 45, as shown in FIG. 3. Therefore, the first valve portion 413 of the first valve body 41 separates away from the seat portion 361 of the partitioning plate 36 and is opened, and a fluid fed into the input port 31 is fed to an actuator (not shown) from the output port 32 through the input-side chamber 34 a and the output-side chamber 34 of the communication chamber 34.

In a state shown in FIG. 3, only the pressure in the output-side chamber 34 b communicating with the output port 32 acts on the second valve body 42. This pressure acts in a direction to push back the moving yoke 54 toward the right in FIG. 3 via the operation rod 55. Meanwhile, the pressure in the input port 31 acts on the first valve body 41. Here, however, since the outer diameter (D1) of the slide portion 411 of the first valve body 41, which is the diameter of the slide surface that is in sliding contact with the first seal 43, is equal to the diameter (D4) of the contact portion, at which the first valve portion 413 of the first valve body 41 comes in contact with the partitioning plate 36, a thrust to the first valve body 41 is not produced by the pressure in the input port 31. When a predetermined voltage is applied to the coil 522 of the electromagnetic coil unit 52 that constitutes the electromagnetic operation means 5 in the state shown in FIG. 3, therefore, a thrust (F1) toward the left in the drawing, which produces in the moving yoke 54, acts against a pushing force (F2) pushing the second valve body 42 toward the right in FIG. 3, which is produced by the pressure in the output-side chamber 34 b, and a spring force (F3) of the first compression coil spring 45. When the sum of (F2) and (F3) is smaller than (F1), i.e., (F2+F3<F1), the state shown in FIG. 3 is maintained, and the fluid fed to the input port 31 continues to be fed to the actuator (not shown) from the output port 32 through the input-side chamber 34 a and the output-side chamber 34 b in the communication chamber 34.

When the sum of (F2) and (F3) becomes larger than (F1), i.e., (F2+F3>F1), on the other hand, the first valve body 41 and the second valve body 42 move toward the right in FIG. 3 against the thrust (F1) that acts on the moving yoke 54. As a result, as shown in FIG. 4, the first valve body 41 and the second valve body 42 move toward the right, whereby the first valve portion 413 of the first valve body 41 halts at a position where it comes in contact with the seat portion 361 of the partitioning plate 36. As a result, the communication between the input port 31 and the output port 32 is shut off, and the fluid is no longer fed to the actuator that is not shown. In a state shown in FIG. 4, when the sum of the force (F2) and a spring force (F4) of the second compression coil spring 46 is still greater than (F1), i.e., (F2+F4>F1), the second valve body 42 moves toward the right in FIG. 4 against the thrust (F1) acting on the moving yoke 54, and a gap is formed between the seat portion 422 a of the second valve body 42 and the second valve portion 414 that constitutes the first valve body 41. Accordingly, the exhaust port 33 communicates with the output-side chamber 34 b of the communication chamber 34 communicating with the output port 32, the gap between the seat portion 422 a of the second valve body 42 and the second valve portion 414 constituting the first valve body 41, the communication passage 415 formed in the first valve body 41, and the first pressure chamber 37. Therefore, the operation fluid in the operation chamber of the actuator (not shown) connected to the output port 32 is exhausted through the exhaust port 33. As the operation fluid exhausts, the pressure in the output-side chamber 34 b drops, the seat surface 422 a of the second valve body 42 comes in contact with the outer peripheral edge of the second valve portion 414 constituting the first valve body 41 at a moment where the sum of (F2) and (F4) comes into agreement with (F1), i.e., (F2+F4=F1), and the pressure proportional control valve 2 is balanced in a state shown in FIG. 4. Therefore, the pressure in the output-side chamber 34 b, i.e., the pressure of the operation fluid acting on the actuator that is not shown, is maintained at a pressure of a moment when the sum of (F2), (F3) and (F4) is in agreement with (F1), i.e., (F2+F3+F4=F1). Since the loads of the first compression coil spring 45 and of the second compression coil spring 46 have been set to very small values that will not almost affect the balance of pressure and further, the strokes of the seat positions of the first valve body 41 and of the second valve body 42 have been determined, the spring forces at the seat position become constant. Therefore, if spring forces of the first compression coil spring 45 and of the second compression coil spring 46 are regarded to be constant, it can be considered that the pushing force (F2) produced by the pressure acting on the second valve unit 42 is equal to a thrust (F1) generated at the moving yoke 54 by the application of a voltage to the coil 522 of the electromagnetic coil unit 52 that constitutes the electromagnetic operation means 5 and hence, the pressure proportional valve 2 works as a pressure proportional valve.

Next, to return the actuator (not shown) back to the position of starting the operation, the supply of electric power to the coil 522 of the electromagnetic coil unit 52 is interrupted to de-energize the electromagnetic solenoid. As a result, the members of the pressure proportional control valve 2 are returned to the state shown in FIG. 1 due to the spring forces of the first compression coil spring 45 and of the second compression coil spring 46. In the state shown in FIG. 1, as described above, the first valve portion 413 of the first valve body 41 comes in contact with the seat portion 361 of the partitioning plate 36 and hence, a gap is formed between the seat portion 422 a of the second valve body 42 and the second valve portion 414 that constitutes the first valve body 41. Accordingly, the communication is interrupted between the input port 31 and the output port 32 and the output port 32 is allowed to communicate with the exhaust port 33 through the output-side chamber 34 b of the communication chamber 34, the gap between the seat portion 422 a of the second valve body 42 and the second valve portion 414 that constitutes the first valve body 41, the communication path 415 formed in the first valve body 41, and the first pressure chamber 37. Consequently, the operation fluid in the operation chamber of the actuator (not shown) connected to the output port 32 is caused to exhaust from the exhaust port 33, and the actuator returns to the position of starting the operation.

The pressure proportional control valve according to the present invention is constituted as described above and is of a type of a three-way valve which controls the input port, output port and exhaust port by using a valve means having a first valve body and a second valve body. Therefore, the feeding and the exhausting can be changed over by using one flow control valve, and since the feeding and exhausting can be changed over without using any other separate valve in combination, the fluid circuit constitution is simplified. Further, the valve means having the first valve body and the second valve body is of the poppet valve type assuring reliable sealing. Besides, even foreign matters such as dust and dirt happen to be adhered on the seat portions, they are swept away with the operation fluid, and no malfunctioning occurs. 

1. A pressure proportional control valve comprising: a valve body having an input port, an output port and an exhaust port; a valve means arranged in said valve body to control a communication with the ports; and an electromagnetic operation means for driving said valve means; which is characterized in: that said valve body is provided with a communication chamber for communicating said input port with said output port, and two valve holes formed, being faced to each other, on both sides of said communication chamber, said communication chamber having an annular partitioning plate arranged therein; that said valve means comprises a first valve body having a slide portion provided at one end portion thereof so as to be slidably fitted to one of said valve holes, a first valve portion having a tapered surface, which is formed at a central portion thereof and comes in contact with a seat portion formed on the inner periphery of said annular partitioning plate, a second valve portion provided at the other end portion thereof, and a communication path that penetrates through in the axial direction and communicates with said exhaust port; a second valve body having a slide portion slidably fitted to the other valve hole, a valve portion that is provided at one end portion thereof and comes in contact with the second valve portion of said valve body, and a communication path that penetrates through in the axial direction and communicates with said exhaust port; a first seal arranged between the slide portion of said first valve body and the inner peripheral surface of said one valve hole; a second seal arranged between the slide portion of said second valve body and the inner peripheral surface of said other valve hole; a first spring for urging said first valve body in a direction in which said first valve portion comes in contact with said seat portion of said partitioning plate; and a second spring that is disposed between said first valve body and said second valve body and urges said first valve body and said second valve body in a direction in which they are separated away from each other; wherein a diameter of the slide surface of said first seal, a diameter of a contact portion at which said first valve portion of said first valve body comes in contact with said seat portion of said partitioning plate and a diameter of a contact portion at which the valve portion of said second valve body comes in contact with said second valve portion of said first valve body are set to be equal; and the diameter of the slide surface of said second seal is set to be larger than the diameter of the slide surface of said first seal; and that when energized, said electromagnetic operation means operates to move said second valve body toward said first valve body side. 